CN113638735B - Manual-automatic integrated non-electric connection drilling inclinometer and measuring method - Google Patents
Manual-automatic integrated non-electric connection drilling inclinometer and measuring method Download PDFInfo
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- CN113638735B CN113638735B CN202110762412.9A CN202110762412A CN113638735B CN 113638735 B CN113638735 B CN 113638735B CN 202110762412 A CN202110762412 A CN 202110762412A CN 113638735 B CN113638735 B CN 113638735B
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- 238000000034 method Methods 0.000 title claims abstract description 22
- 238000005553 drilling Methods 0.000 title claims abstract description 21
- 239000000523 sample Substances 0.000 claims abstract description 121
- 230000007246 mechanism Effects 0.000 claims abstract description 114
- 238000005259 measurement Methods 0.000 claims abstract description 24
- 238000004804 winding Methods 0.000 claims abstract description 12
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- 230000005484 gravity Effects 0.000 claims description 4
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- 238000003860 storage Methods 0.000 claims description 3
- 238000005096 rolling process Methods 0.000 claims description 2
- 238000012544 monitoring process Methods 0.000 abstract description 25
- 230000008054 signal transmission Effects 0.000 abstract description 5
- 230000009286 beneficial effect Effects 0.000 abstract description 2
- 229910000831 Steel Inorganic materials 0.000 description 6
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- 238000013075 data extraction Methods 0.000 description 1
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- 238000011065 in-situ storage Methods 0.000 description 1
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- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B47/00—Survey of boreholes or wells
- E21B47/02—Determining slope or direction
- E21B47/022—Determining slope or direction of the borehole, e.g. using geomagnetism
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- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B23/00—Apparatus for displacing, setting, locking, releasing or removing tools, packers or the like in boreholes or wells
- E21B23/14—Apparatus for displacing, setting, locking, releasing or removing tools, packers or the like in boreholes or wells for displacing a cable or a cable-operated tool, e.g. for logging or perforating operations in deviated wells
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Abstract
The invention provides a manual-automatic integrated non-electric connection type landslide drilling inclinometer and a measuring method, wherein an inclination measuring probe is used for completing drilling inclination measurement; the hoisting mechanism is connected with the inclination measuring probe through a pull rope; the left and right ends of the winding mechanism are respectively fixed with a first tooth piece of the automatic clutch and a first tooth piece of the manual clutch, a driving shaft of the electric driving mechanism is fixed with a second tooth piece of the automatic clutch, the second tooth piece of the automatic clutch can be selectively meshed with or separated from the first tooth piece of the automatic clutch, a driving shaft of the manual driving mechanism is fixed with a second tooth piece of the manual clutch, and the second tooth piece of the manual clutch can be selectively meshed with or separated from the first tooth piece of the manual clutch. The technical scheme provided by the invention has the beneficial effects that: the device breaks through the limitation on the depth of the monitoring hole caused by the problems of limited signal transmission distance, large remote power supply voltage drop, great cable self weight and the like, and simultaneously gives consideration to manual and automatic measurement, the measurement mode is flexibly and conveniently switched, and the comprehensive measurement cost is low.
Description
Technical Field
The invention relates to the technical field of geological disaster monitoring and prevention, in particular to a manual-automatic integrated non-electric connection drilling inclinometer and a measuring method.
Background
Landslide monitoring is an important component in the field of geological disaster monitoring, a large amount of geological information including landslide deformation characteristics, changes of physical and mechanical properties of a slide material, changes of underground landslide environment such as seepage flow velocity and flow direction and the like is obtained through continuous and reliable monitoring means, and evaluation, prediction and treatment are effective control means of landslide geological disasters on the basis of the geological information. Displacement monitoring is an important method for judging landslide stability, and deep displacement monitoring is particularly important for revealing deep deformation characteristics of landslides and judging the position and the deformation rate of a sliding surface.
The borehole inclinometer has a long application history in landslide deep displacement monitoring, and is a deep deformation monitoring device which is most widely applied in the engineering field due to high precision and good reliability. The existing drilling inclinometer technology is mainly divided into a fixed inclinometer and a sliding inclinometer. The former is based on the combination of a plurality of inclinometers embedded in the in-situ drilling hole and an automatic data acquisition receiving and transmitting system, and has the characteristics of real-time monitoring, flexible gauge length configuration, durability and reusability. However, due to the arrangement characteristics, the single-time layout cost is high, and the mountable measurement point number in the same deep displacement drilling is limited and the measuring range is limited. The sliding inclinometer has the advantages of low price, simple operation and capability of truly reflecting the deformation state of the landslide. However, this measurement method is time and labor consuming and the measurement results may also generate large random errors due to the operation differences of different operators. In addition, the landslide deformation speed is divided into a plurality of stages according to the evolution process, and different stages correspond to the requirements of different monitoring frequencies and monitoring speeds.
Disclosure of Invention
In view of the above, to solve the above problems, embodiments of the present invention provide a manual-automatic integrated non-electric connection drilling inclinometer and a measurement method.
The embodiment of the invention provides a manual-automatic integrated non-electric connection drilling inclinometer, which comprises:
the inclination measuring probe is placed into the inclination measuring pipe through the pull rope, the measurable drilling depth is not limited by electric connection, and the acquisition and storage of inclination data of each measuring point position in the inclination measuring pipe are completed;
the probe traction device comprises a hoisting mechanism, an electric driving mechanism and a manual driving mechanism; a pull rope of the hoisting mechanism is connected with the inclination measuring probe and lifts the inclination measuring probe upwards; a first tooth sheet of an automatic clutch and a first tooth sheet of a manual clutch are respectively fixed at the left and right ends of the winding mechanism, a second tooth sheet of the automatic clutch is fixed on a driving shaft of the electric driving mechanism, the second tooth sheet of the automatic clutch can be selectively meshed with or separated from the first tooth sheet of the automatic clutch, a second tooth sheet of the manual clutch is fixed on the driving shaft of the manual driving mechanism, and the second tooth sheet of the manual clutch can be selectively meshed with or separated from the first tooth sheet of the manual clutch;
when the second tooth piece of the automatic clutch is meshed with the first tooth piece of the automatic clutch, the driving shaft of the electric driving mechanism drives the hoisting mechanism to lift the inclination measuring probe upwards regularly and intermittently, and when the second tooth piece of the manual clutch is meshed with the first tooth piece of the manual clutch, the driving shaft of the manual driving mechanism drives the hoisting mechanism to lift the inclination measuring probe upwards regularly and intermittently.
Furthermore, the probe traction device further comprises a base, the hoisting mechanism is fixed on the base, and the electric driving mechanism and the manual driving mechanism are movably arranged on the base and are respectively positioned on the left side and the right side of the hoisting mechanism.
Furthermore, the probe traction device further comprises a gantry support, a slide rail extending in the left-right direction is arranged on the base, a slide block in sliding fit with the slide rail is fixed at the bottom of the gantry support, the hoisting mechanism is located on the inner side of the gantry support, the electric driving mechanism and the manual driving mechanism are respectively fixed on the gantry support, the electric driving mechanism and the manual driving mechanism are respectively located on the left side and the right side of the hoisting mechanism and have gaps, and the hoisting mechanism is located between the second tooth piece of the automatic clutch and the second tooth piece of the manual clutch and has gaps.
Furthermore, a gear shifting lever is fixed at the top of the gantry support, the probe traction device further comprises a case shell, an opening at the lower side of the case shell covers the base, the hoisting mechanism, the electric driving mechanism and the manual driving mechanism are located in the case shell, a gear hole is formed in the case shell at a position opposite to the gear shifting lever, three gear clamping grooves are formed in the side wall of the gear hole in the left-right direction, an elastic sheet is arranged on one side, facing the gear clamping grooves, of the gear shifting lever, the elastic sheet is located in the gear clamping grooves, and the upper end of the gear shifting lever is located above the case shell;
when the gear shifting lever is positioned in the gear clamping groove at the rightmost side, the first tooth piece of the manual clutch is meshed with the second tooth piece of the manual clutch; when the gear shifting lever is positioned in the middle gear clamping groove, the first tooth piece of the manual clutch and the second tooth piece of the manual clutch are arranged at intervals, and the first tooth piece of the automatic clutch and the second tooth piece of the automatic clutch are arranged at intervals; when the gear shifting lever is positioned in the gear clamping groove at the leftmost side, the first tooth piece of the automatic clutch is meshed with the second tooth piece of the automatic clutch.
Furthermore, the electric driving mechanism comprises a stepping driving motor and a motor reducer, and the motor reducer is connected with the stepping driving motor and fixed on the gantry support.
Furthermore, the manual driving mechanism comprises a manual rocking handle and a manual gear speed regulator, the manual gear speed regulator is fixed on the gantry support, and the manual rocking handle is connected with the manual gear speed regulator to drive the manual gear speed regulator to rotate.
Further, the probe traction device further comprises a position metering mechanism, wherein the position metering mechanism comprises a rotary encoder and a rotary coupling wheel;
the rotary encoder is arranged on the base, the rotary coupling wheel is arranged on an input shaft of the rotary encoder, the pull rope is wound on the rotary coupling wheel for a circle, and the rotary encoder is used for acquiring the rotating distance of the rotary coupling wheel so as to obtain the traction distance of the pull rope.
Furthermore, the position metering mechanism further comprises a rope arranging cover, the rope arranging cover is fixed on the base, the rotary coupling wheel is located in the rope arranging cover, a through shaft hole penetrates through the position, opposite to the input shaft of the rotary encoder, of the rope arranging cover, and through wire holes are formed in the rope arranging cover and the two ends of the pull rope respectively.
Furthermore, the inclinometer probe comprises a probe tube shell, guide roller devices are respectively arranged at the upper end and the lower end of the probe tube shell, the guide roller devices are used for rolling in a guide groove of the inclinometer tube, an inclinometer circuit module, an interface module and a power module are fixed in the probe tube shell, the inclinometer circuit module is used for collecting and storing inclinometer data, the interface module is used for being connected with external equipment to realize transmission of the inclinometer data, and the power module is electrically connected with the inclinometer circuit module and used for supplying power.
The embodiment of the invention also provides a measuring method, which utilizes the manual-automatic integrated non-electric connection type landslide drilling inclinometer, and comprises the following steps:
s1, starting a measurement mode of an inclinometer probe, and placing the inclinometer probe into an inclinometer pipe;
s2, separating a first tooth sheet of the automatic clutch from a second tooth sheet of the automatic clutch, separating the first tooth sheet of the manual clutch from the second tooth sheet of the manual clutch, and sliding the inclinometer probe to the bottom of the inclinometer pipe under the action of gravity;
s3, meshing the first tooth piece of the automatic clutch with the second tooth piece of the automatic clutch, separating the first tooth piece of the manual clutch from the second tooth piece of the manual clutch, starting a probe traction device, and automatically finishing the intermittent lifting of the inclinometer probe by the probe traction device until the inclinometer probe rises to the pipe orifice of the inclinometer pipe and finishes the lifting, so as to finish the measurement of the inclinometer pipe;
when the electric quantity of the inclination measuring probe is insufficient, separating a first tooth sheet of the automatic clutch from a second tooth sheet of the automatic clutch, meshing the first tooth sheet of the manual clutch with the second tooth sheet of the manual clutch, manually and continuously rotating a manual rocking handle, and transmitting intermittent motion through a manual gear speed regulator to realize intermittent lifting of the inclination measuring probe until the inclination measuring probe reaches an orifice to finish measurement;
s4, taking out the inclination measuring probe from the inclination measuring pipe, closing the measuring mode of the inclination measuring probe, and obtaining inclination measuring data measured by the inclination measuring probe;
and S5, extracting effective measuring point data sections from the inclination measuring data, intercepting the stable data sections, calculating the average value, and calculating the inclination angle information of the corresponding measuring point position.
The technical scheme provided by the embodiment of the invention has the following beneficial effects:
the traditional cable connection method is abandoned by connecting the probe traction device and the inclinometer through the pull rope, the adopted pull rope non-electric connection mode breaks through the limitation on the depth of the monitoring hole caused by the problems of limited signal transmission distance, large power supply voltage drop at the far end, great cable self-weight and the like, the manual and automatic measurement is considered, the measurement mode is flexibly and conveniently switched, and the comprehensive measurement cost is low.
The automatic gear monitoring speed and frequency in the probe traction device are adjustable, so that the low-frequency monitoring in a landslide creep stage can be met, the high-frequency and quick-response monitoring requirements in a landslide severe-slip or accelerated-deformation stage can be met, and the probe traction device has important significance in deep deformation monitoring of landslide geological disasters. A traditional cable connection method is abandoned between the probe traction device and the inclination measuring probe, and the adopted non-electric connection mode of the steel wire rope removes the limitation of monitoring hole depth caused by the problems of limited signal transmission distance, large remote power supply voltage drop, heavy cable self-weight and the like. The method has the characteristics of three functions and wide application scene, can work all weather, all globe and all time, has mature technology, reasonable design, good economical efficiency and convenient popularization, and is suitable for monitoring deep deformation of landslide geological disasters.
Drawings
FIG. 1 is a schematic structural diagram of an embodiment of a probe traction device in a manual-automatic integrated non-electric connection type landslide drilling inclinometer provided by the invention;
FIG. 2 is a schematic diagram of the internal structure of the probe traction device in FIG. 1;
FIG. 3 is a schematic view of a portion of the probe traction device of FIG. 2;
FIG. 4 is a cross-sectional view of the probe retractor of FIG. 3 (with the gear shifter in automatic gear);
FIG. 5 is a cross-sectional view of the probe retractor of FIG. 3 (with the shift lever in neutral);
FIG. 6 is a cross-sectional view of the probe retractor of FIG. 3 (with the shift lever in manual shift);
FIG. 7 is a schematic structural view of an embodiment of an inclinometer probe in the manual-automatic integrated non-electric connection type landslide borehole inclinometer provided by the invention;
FIG. 8 is a schematic diagram of a manual and automatic integrated ropeless landslide borehole inclinometer and field application provided by the present invention;
FIG. 9 is a data pattern graph of an embodiment of a data extraction method provided by the present invention;
fig. 10 is a schematic flow chart of a measurement method provided by the present invention.
In the figure: the device comprises an inclination measuring probe 100, a probe traction device 200, an inclination measuring tube 300, a probe tube shell 1, a guide roller device 2, a guide support 2a, a guide roller 2b, an inclination measuring circuit module 3, an interface module 4, a power supply module 5, a base 6, a slide rail 6a, a control circuit board 6b, a power battery 6c, a gantry support 7, a slide block 7a, a gear shift lever 7b, an elastic sheet 7c, a gear clamping groove 7d, a case shell 8, a lifting handle 8a, a gear hole 8b, a winding mechanism 9, a drawing rope 9a, a winding reel support 9c, an electric driving mechanism 10, a stepping driving motor 10a, a motor reducer 10b, a driving shaft 10c of the electric driving mechanism, a manual driving mechanism 11, a manual rocking handle 11a, a manual gear speed regulator 11b, a driving shaft 11c of the manual driving mechanism, a position metering mechanism 12, a rotary encoder 12a, a rotary coupling wheel 12b, a rope arranging cover 12c, a pipe orifice support cover 12d, a flexible sleeve 12e, a metering support 12f, a first tooth clutch sheet 13 of the manual driving mechanism, a second tooth clutch sheet 14, a tooth clutch sheet 16 and effective data of a tooth clutch sheet.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be further described with reference to the accompanying drawings.
Referring to fig. 1 to 8, an embodiment of the present invention provides a manual-automatic integrated non-electrical connection type landslide borehole inclinometer, which includes an inclinometer probe 100 and a probe traction device 200.
The inclination measuring probe 100 is lowered into the inclination measuring pipe 300 through the pull rope 9b, the independent closed system of the inclination measuring probe finishes the collection and storage of the inclination data of the positions of all measuring points in the inclination measuring pipe 300, the depth of a measurable hole is not limited by electric connection, and the positions of all measuring points in the hole are marked by the intermittent data characteristics. Specifically, referring to fig. 7, the inclinometer probe 100 includes a probe tube housing 1, guide roller devices 2 are respectively disposed at upper and lower ends of the probe tube housing 1, each guide roller device 2 includes a guide bracket 2a and a guide roller 2b, the guide bracket 2a is mounted on the probe tube housing 1, and the guide roller 2b is rotatably mounted on the guide bracket 2 a. A guide groove extending in the vertical direction is formed in the inclinometer tube 300, the guide roller device 2 rolls in the guide groove, and the inclinometer probe 100 is clamped in the guide groove of the inclinometer tube 300 to prevent the inclinometer probe from rotating. An inclinometry circuit module 3, an interface module 4 and a power module 5 are fixed in the probe shell 1, the inclinometry circuit module 3 is used for collecting and storing inclinometry data, the interface module 4 is used for being connected with external equipment to realize transmission of the inclinometry data, and the power module 5 is electrically connected with the inclinometry circuit module 3 and used for supplying power.
Referring to fig. 1 to 6, the probe traction device 200 includes a base 6, a gantry support 7, a chassis housing 8, a hoisting mechanism 9, an electric driving mechanism 10, a manual driving mechanism 11, and a position measuring mechanism 12.
The hoisting mechanism 9 is fixed on the base 6, the hoisting mechanism 9 is in the prior art and comprises a reel 9a and a pull rope 9b, the reel 9a is fixed on the base 6 through a hoisting support 9c, one end of the pull rope 9b is wound on the reel 9a, the other end of the pull rope 9b is connected with the inclinometer probe 100 and used for lifting the inclinometer probe 100 upwards, the pull rope 9b is specifically a steel wire rope, the inclinometer probe 100 is placed in the inclinometer pipe 300 under the traction of the steel wire rope, and the inclinometer probe 100 is lifted by the steel wire rope intermittently during measurement. In this embodiment, the probe traction device 200 intermittently pulls the inclinometer probe 100 upward at equal intervals, and provides the inclinometer probe 100 with approximate qualitative movement characteristics for identifying the data segment position of the measurement point offline. The left and right ends of the winding mechanism 9 are respectively fixed with a first tooth piece 13 of an automatic clutch and a first tooth piece 14 of a manual clutch, and the automatic clutch and the manual clutch are jaw clutches.
The electric driving mechanism 10 is movably arranged on the base 6 and is positioned on the left side of the winding mechanism 9. And a second tooth sheet 15 of the automatic clutch is fixed on a driving shaft 10c of the electric driving mechanism, and the second tooth sheet 15 of the automatic clutch can be selectively meshed with or separated from the first tooth sheet 13 of the automatic clutch. The manual driving mechanism 11 is movably arranged on the base 6 and is positioned on the right side of the winding mechanism 9. The driving shaft 11c of the manual driving mechanism is fixed with a second tooth piece 16 of the manual clutch, and the second tooth piece 16 of the manual clutch can be selectively meshed with or separated from the first tooth piece 14 of the manual clutch.
When the second tooth piece 15 of the automatic clutch is meshed with the first tooth piece 13 of the automatic clutch, the driving shaft 10c of the electric driving mechanism drives the winding mechanism 9 to lift the inclinometer probe 100 upwards regularly and intermittently, and when the second tooth piece 16 of the manual clutch is meshed with the first tooth piece 14 of the manual clutch, the driving shaft 11c of the manual driving mechanism drives the winding mechanism 9 to lift the inclinometer probe 100 upwards regularly and intermittently.
Specifically, the base 6 is provided with slide rails 6a extending in the left-right direction, the bottom of the gantry support 7 is fixed with slide blocks 7a in sliding fit with the slide rails 6a, in this embodiment, the two slide rails 6a are arranged at intervals in the front-back direction, and the bottom of the gantry support 7 is correspondingly provided with the two slide blocks 7a, so that the moving stability of the gantry support 7 can be enhanced. The middle part of the hoisting bracket 9c is arched to allow the sliding rail 6a to pass through.
The electric driving mechanism 10 and the manual driving mechanism 11 are respectively fixed on the gantry support 7, the hoisting mechanism 9 is positioned on the inner side of the gantry support 7, and the electric driving mechanism 10 and the manual driving mechanism 11 are respectively positioned on the left side and the right side of the hoisting mechanism 9 and have gaps. The electric driving mechanism 10 and the manual driving mechanism 11 can be installed inside the gantry support 7, in this embodiment, the electric driving mechanism 10 and the manual driving mechanism 11 are respectively fixed on the left side and the right side of the gantry support 7, a position of the gantry support 7 opposite to the driving shaft 11c of the electric driving mechanism 10 and the manual driving mechanism is provided with a abdicating hole in a penetrating manner, one end of the two driving shafts penetrating through the abdicating hole in the gantry support 7 is respectively and correspondingly fixed with the second tooth piece 15 of the automatic clutch and the second tooth piece 16 of the manual clutch, and the winding mechanism 9 is located between the second tooth piece 15 of the automatic clutch and the second tooth piece 16 of the manual clutch and has a gap.
By the arrangement, the gantry support 7 can be moved leftwards and rightwards, the gantry support 7 is moved leftwards, the first tooth piece 13 of the automatic clutch on the left side of the reel 9a is meshed with the second tooth piece 15 of the automatic clutch on the electric driving mechanism 10, and the driving shaft 10c of the electric driving mechanism can drive the reel 9a to rotate, so that the electric traction inclination measuring probe 100 is realized. The gantry support 7 is moved rightwards, so that a first tooth piece 14 of a manual clutch on the right side of the reel 9a is meshed with a second tooth piece 16 of the manual clutch on the manual driving mechanism 11, and a driving shaft 11c of the manual driving mechanism can drive the reel 9a to rotate, so that the inclination measuring probe 100 is manually pulled. And moving the reel 9a to a position between the second tooth piece 15 of the automatic clutch and the second tooth piece 16 of the manual clutch, so that the first tooth piece 13 of the automatic clutch is separated from the second tooth piece 15 of the automatic clutch, the first tooth piece 14 of the manual clutch is separated from the second tooth piece 16 of the manual clutch, the automatic clutch is in a neutral position, the steel wire rope is in a loose state, and the inclinometer probe 100 can move downwards to the bottom of the inclinometer pipe 300 under the action of the gravity of the inclinometer probe.
Specifically, the electric driving mechanism comprises a stepping driving motor 10a and a motor reducer 10b, the motor reducer 10b is connected with the stepping driving motor 10a and fixed on the gantry support 7, and a driving shaft 10c of the electric driving mechanism is installed on the motor reducer 10 b.
The manual driving mechanism 11 comprises a manual rocking handle 11a and a manual gear speed regulator 11b, the manual gear speed regulator 11b is fixed on the gantry support 7, the manual rocking handle 11a is connected with the manual gear speed regulator 11b to drive the manual gear speed regulator 11b to rotate, and a driving shaft 11c of the manual driving mechanism is installed on the manual gear speed regulator 11 b. An intermittent transmission mechanism is arranged in the manual gear speed regulator 11b, and when the manual rocking handle 11a is continuously rotated, an output shaft of the manual gear speed regulator 11b outputs intermittent rotation.
And a control circuit board 6b and a power battery 6c are fixed on the base 6 and are used for controlling the working process of the probe traction device 200, positioning the position of a measuring point and supplying power.
An opening at the lower side of the case shell 8 covers the base 6 to form a shade for protecting internal components. A lifting handle 8a is arranged at the top of the case shell 8, so that the whole device can be moved conveniently. The winding mechanism 9, the electric driving mechanism 10 and the manual driving mechanism 11 are located in the case shell 8, a through hole is formed in the case shell 8 in a penetrating mode at a position opposite to the manual rocking handle 11a, and the manual rocking handle 11a penetrates out of the through hole.
In order to adjust the gear, a gear shifting lever 7b is fixed at the top of the gantry support 7, a gear hole 8b is formed in the position, opposite to the gear shifting lever 7b, of the chassis housing 8, three gear clamping grooves 7d are formed in the side wall of the gear hole 8b in the left-right direction, the gear shifting lever 7b faces towards one side of the gear clamping grooves 7d and is provided with an elastic sheet 7c, the elastic sheet 7c is located in the gear clamping grooves 7d, and the upper end of the gear shifting lever 7b is located above the chassis housing 8, so that an operator can shift the gear. When the gear shift lever 7b is located in the rightmost gear slot 7d, the first tooth piece 14 of the manual clutch is engaged with the second tooth piece 16 of the manual clutch (see fig. 6, the gear shift lever 7b is located in the manual gear); when the gear shift lever 7b is located in the middle gear slot 7d, the first tooth piece 14 of the manual clutch and the second tooth piece 16 of the manual clutch are arranged at intervals, and the first tooth piece 13 of the automatic clutch and the second tooth piece 15 of the automatic clutch are arranged at intervals (please refer to fig. 5, the gear shift lever 7b is located in a neutral position); when the gear shift lever 7b is located in the leftmost gear slot 7d, the first tooth piece 13 of the automatic clutch is engaged with the second tooth piece 15 of the automatic clutch (please refer to fig. 4, the gear shift lever 7b is located in the automatic gear), so that an operator can conveniently judge the gear.
Specifically, keep off position driving lever 7b and be equipped with the notch that the notch moved position draw-in groove 7d, shell fragment 7c passes through spring coupling in the notch, shell fragment 7c one end is located the notch, the other end is located outside the notch, notch and shell fragment 7c are the triangle-shaped setting on the cross-section, keep off position driving lever 7b to the removal in-process about, the spring is in compression state, shell fragment 7c promotes shell fragment 7c to the notch in under the thrust effect of spring, carry out the clamper to portal frame 7 horizontal slip position, form automatic fender position (figure 4), neutral gear position (figure 5) and manual three fender position (figure 6) of keeping off the position.
The position metering mechanism 12 comprises a rotary encoder 12a, a rotary coupling wheel 12b, a rope arranging cover 12c, a nozzle supporting cover 12d and a flexible sleeve 12e, wherein the rotary encoder 12a is installed on the base 6, the rotary encoder 12a is installed on the base 6 through a metering support 12f, the rotary coupling wheel 12b is installed on an input shaft of the rotary encoder 12a, the pull rope 9b is wound on the rotary coupling wheel 12b for a circle, and the rotary encoder 12a is used for acquiring the rotating distance of the rotary coupling wheel 12b, so that the pulling distance of the pull rope 9b is acquired. The rope arranging cover 12c is fixed on the base 6, the rotary coupling wheel 12b is positioned in the rope arranging cover 12c, a through hole is arranged at the position, opposite to the input shaft of the rotary encoder 12a, of the rope arranging cover 12c in a penetrating mode, and through holes are arranged at the two ends of the rope arranging cover 12c and the two ends of the pull rope 9b in a penetrating mode respectively, so that the pulling distance of the pull rope 9b can be accurately transmitted to the rotary encoder 12a, and the accuracy of position control of the measuring point is guaranteed. The top of the inclinometer tube 300 is covered with a tube opening supporting cover 12d, and the tube opening supporting cover 12d is provided with a through hole for the pull rope 9b to pass through. The flexible sleeve 12e is sleeved outside the pull rope 9b, the flexible sleeve 12e is positioned between the nozzle support cover 12d and the rope arranging cover 12c, and two ends of the flexible sleeve are respectively connected with the nozzle support cover 12d and the rope arranging cover 12 c. The flexible sleeve 12e is not telescopic in the axial direction, but can generate flexural deformation, and the site placement of the probe traction device 200 is not limited by the spatial position.
Referring to fig. 10, based on the manual-automatic integrated non-electric connection type landslide drilling inclinometer, the measurement mode of the inclinometer probe 100 is started, the inclinometer probe 100 is placed in the inclinometer tube 300, and the tube opening support cover 12d is tightly fastened to the tube opening of the inclinometer tube 300.
And separating the first tooth piece 13 of the automatic clutch from the second tooth piece 15 of the automatic clutch, separating the first tooth piece 14 of the manual clutch from the second tooth piece 16 of the manual clutch, specifically, shifting the gear shift lever 7b to a neutral gear, and sliding the inclinometer probe 100 to the bottom of the inclinometer tube 300 under the action of gravity.
The first tooth piece 13 of the automatic clutch is meshed with the second tooth piece 15 of the automatic clutch, the first tooth piece 14 of the manual clutch is separated from the second tooth piece 16 of the manual clutch, specifically, the gear shift lever 7b is shifted to an automatic gear, the probe traction device 200 is started, the probe traction device 200 automatically finishes intermittent lifting of the inclinometer probe 100 until the inclinometer probe 100 rises to the pipe orifice of the inclinometer pipe 300 and is blocked by the pipe orifice supporting cover 12d, the probe traction device 200 detects a sudden load change and finishes lifting, measurement of the inclinometer pipe 300 is finished, and the probe traction device 200 automatically stops lifting of the inclinometer probe 100.
When the power battery 6c in the inclinometer probe 100 is insufficient in electric quantity, the first tooth piece 13 of the automatic clutch is separated from the second tooth piece 15 of the automatic clutch, the first tooth piece 14 of the manual clutch is meshed with the second tooth piece 16 of the manual clutch, specifically, the gear shift lever 7b is shifted to a manual gear, the manual crank 11a is manually and continuously rotated, intermittent motion is transmitted through the manual gear speed regulator 11b, intermittent lifting of the inclinometer probe 100 is achieved, and the inclinometer probe 100 reaches an orifice to finish measurement.
The nozzle support cover 12d is removed, the inclinometer probe 100 is taken out of the inclinometer tube 300, the measurement mode of the inclinometer probe 100 is closed, and the inclinometer data measured by the inclinometer probe 100 is acquired, specifically copied through the interface module 4.
And extracting an effective measuring point data section 17 from the inclination measuring data, and intercepting a stable data section to calculate the average value and then calculating the inclination information of the corresponding measuring point position. The inclination measuring data type is as shown in fig. 9, because the inclination measuring probe 100 is intermittently pulled up in the inclination measuring tube 300 in the measuring process, the recorded data type is the intermittent stable and severe fluctuation state shown in fig. 9, the inclination measuring circuit module 3 records the effective measuring point data section 17 in the intermittent process, and the inclination measuring circuit module 3 records the lifting process data section 18 corresponding to each measuring point position of the inclination measuring tube 300 in the lifting process. When data are extracted, the effective measuring point data section 17 is identified according to the characteristics of the data section, and a section of stable value is intercepted to obtain the average value so as to obtain the inclination angle information of the corresponding measuring point.
The technical scheme provided by the invention is that,
the probe traction device 200 is connected with the inclinometer probe 100 through the pull rope 9b, the traditional cable connection method is abandoned, the adopted pull rope 9b non-electric connection mode breaks through the limitation on the depth of the monitoring hole caused by the problems of limited signal transmission distance, large power supply voltage drop at the far end, heavy cable self-weight and the like, meanwhile, manual and automatic measurement is considered, the measurement mode is flexibly and conveniently switched, and the comprehensive measurement cost is low.
The automatic gear monitoring speed and frequency in the probe traction device 200 are adjustable, so that the low-frequency monitoring in a landslide creep stage can be met, the high-frequency and quick-response monitoring requirements in a landslide severe-slip or accelerated-deformation stage can be met, and the probe traction device has important significance in deep deformation monitoring of landslide geological disasters. The traditional cable connection method is abandoned between the probe traction device 200 and the inclinometer probe 100, and the adopted non-electric connection mode of the steel wire rope removes the limitation of monitoring hole depth caused by the problems of limited signal transmission distance, large remote power supply voltage drop, heavy cable self-weight and the like. The method has the characteristics of three functions and wide application scene, can work all weather, all globe and all time, has mature technology, reasonable design, good economical efficiency and convenient popularization, and is suitable for monitoring deep deformation of landslide geological disasters.
In this document, the terms front, back, upper, lower and the like in the drawings are used for the sake of clarity and convenience only for the components are located in the drawings and the positions of the components relative to each other. It is to be understood that the use of the directional terms should not be taken to limit the scope of the claims.
The features of the embodiments and embodiments described herein above may be combined with each other without conflict.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, which is intended to cover any modifications, equivalents, improvements, etc. within the spirit and scope of the present invention.
Claims (6)
1. The utility model provides an integrative non-electric connection formula landslide drilling inclinometer of manual-automatic, which characterized in that includes:
the inclination measuring probe is placed into the inclination measuring pipe through the pull rope, can measure the drilling depth without being limited by electric connection, and finishes the acquisition and storage of inclination data of each measuring point position in the inclination measuring pipe;
the probe traction device comprises a hoisting mechanism, an electric driving mechanism and a manual driving mechanism; a pull rope of the hoisting mechanism is connected with the inclination measuring probe and lifts the inclination measuring probe upwards; a first tooth sheet of an automatic clutch and a first tooth sheet of a manual clutch are respectively fixed at the left and right ends of the winding mechanism, a second tooth sheet of the automatic clutch is fixed on a driving shaft of the electric driving mechanism, the second tooth sheet of the automatic clutch can be meshed with or far away from the first tooth sheet of the automatic clutch, a second tooth sheet of the manual clutch is fixed on the driving shaft of the manual driving mechanism, and the second tooth sheet of the manual clutch can be meshed with or far away from the first tooth sheet of the manual clutch;
when the second tooth piece of the automatic clutch is meshed with the first tooth piece of the automatic clutch, the driving shaft of the electric driving mechanism drives the hoisting mechanism to lift the inclinometer probe upwards regularly and intermittently, and when the second tooth piece of the manual clutch is meshed with the first tooth piece of the manual clutch, the driving shaft of the manual driving mechanism drives the hoisting mechanism to lift the inclinometer probe upwards regularly and intermittently;
the probe traction device also comprises a base, the hoisting mechanism is fixed on the base, and the electric driving mechanism and the manual driving mechanism are movably arranged on the base and are respectively positioned at the left side and the right side of the hoisting mechanism;
the probe traction device also comprises a gantry support, a sliding rail extending in the left-right direction is arranged on the base, a sliding block in sliding fit with the sliding rail is fixed at the bottom of the gantry support, the hoisting mechanism is positioned on the inner side of the gantry support, the electric driving mechanism and the manual driving mechanism are respectively fixed on the gantry support, the electric driving mechanism and the manual driving mechanism are respectively positioned on the left side and the right side of the hoisting mechanism and are provided with gaps, and the hoisting mechanism is positioned between the second tooth piece of the automatic clutch and the second tooth piece of the manual clutch and is provided with a gap;
a gear shifting rod is fixed at the top of the gantry support, the probe traction device further comprises a case shell, an opening at the lower side of the case shell covers the base, the hoisting mechanism, the electric driving mechanism and the manual driving mechanism are positioned in the case shell, a gear hole is formed in the case shell at the position opposite to the gear shifting rod, three gear clamping grooves are formed in the side wall of the gear hole along the left-right direction, elastic pieces are arranged on one sides, facing the gear clamping grooves, of the gear shifting rod, the elastic pieces are positioned in the gear clamping grooves, and the upper end of the gear shifting rod is positioned above the case shell;
when the gear shifting lever is positioned in the gear clamping groove at the rightmost side, the first tooth piece of the manual clutch is meshed with the second tooth piece of the manual clutch; when the gear shifting lever is positioned in the middle gear clamping groove, the first tooth piece of the manual clutch and the second tooth piece of the manual clutch are arranged at intervals, and the first tooth piece of the automatic clutch and the second tooth piece of the automatic clutch are arranged at intervals; when the gear shifting lever is positioned in the gear clamping groove at the leftmost side, the first tooth piece of the automatic clutch is meshed with the second tooth piece of the automatic clutch;
the manual driving mechanism comprises a manual rocking handle and a manual gear speed regulator, the manual gear speed regulator is fixed on the gantry support, and the manual rocking handle is connected with the manual gear speed regulator to drive the manual gear speed regulator to rotate.
2. The manual-automatic integrated non-electric connection type landslide drilling inclinometer of claim 1, wherein the electric driving mechanism comprises a stepping driving motor and a motor reducer, wherein the motor reducer is connected with the stepping driving motor and fixed on the gantry support.
3. The manual-automatic integrated non-electric connection type landslide drilling inclinometer of claim 1, wherein the probe traction device further comprises a position metering mechanism, wherein the position metering mechanism comprises a rotary encoder and a rotary coupling wheel;
the rotary encoder is installed on the base, the rotary coupling wheel is installed on an input shaft of the rotary encoder, the pull rope is wound on the rotary coupling wheel for a circle, and the rotary encoder is used for obtaining the rotating distance of the rotary coupling wheel, so that the pulling distance of the pull rope is obtained.
4. The manual-automatic integrated non-electric connection type landslide drilling inclinometer according to claim 3, wherein the position measuring mechanism further comprises a rope arranging cover, the rope arranging cover is fixed on the base, the rotary coupling wheel is positioned in the rope arranging cover, a through shaft hole is formed in the position, opposite to the input shaft of the rotary encoder, of the rope arranging cover in a penetrating mode, and a through wire hole is formed in the positions, corresponding to the two ends of the pull rope, of the rope arranging cover in a penetrating mode.
5. The manual-automatic integrated non-electric connection type landslide drilling inclinometer of claim 1, wherein the inclinometer probe comprises a probe tube shell, guide roller devices are respectively arranged at the upper end and the lower end of the probe tube shell, the guide roller devices are used for rolling in a guide groove of the inclinometer tube, an inclinometer circuit module, an interface module and a power supply module are fixed in the probe tube shell, the inclinometer circuit module is used for collecting and storing inclinometer data, the interface module is used for being connected with external equipment to realize transmission of the inclinometer data, and the power supply module is electrically connected with the inclinometer circuit module and used for supplying power.
6. A measuring method, characterized in that, using the manual-automatic integrated non-electric connection type landslide drilling inclinometer according to any one of claims 1 to 5, the method comprises the following steps:
s1, starting a measurement mode of an inclinometer probe, and placing the inclinometer probe into an inclinometer pipe;
s2, separating a first tooth sheet of the automatic clutch from a second tooth sheet of the automatic clutch, separating the first tooth sheet of the manual clutch from the second tooth sheet of the manual clutch, and sliding the inclinometer probe to the bottom of the inclinometer pipe under the action of gravity;
s3, meshing a first tooth sheet of the automatic clutch with a second tooth sheet of the automatic clutch, separating the first tooth sheet of the manual clutch from the second tooth sheet of the manual clutch, starting a probe traction device, and automatically finishing the intermittent lifting of the inclinometer probe by the probe traction device until the inclinometer probe rises to the pipe orifice of the inclinometer pipe and finishes the lifting, thereby finishing the measurement of the inclinometer pipe;
when the electric quantity of the inclinometer probe is insufficient, separating a first tooth sheet of the automatic clutch from a second tooth sheet of the automatic clutch, meshing the first tooth sheet of the manual clutch with the second tooth sheet of the manual clutch, manually and continuously rotating the manual crank handle, and transmitting intermittent motion through the manual gear speed regulator to realize intermittent lifting of the inclinometer probe until the inclinometer probe reaches an orifice to finish measurement;
s4, taking out the inclination measuring probe from the inclination measuring pipe, closing the measuring mode of the inclination measuring probe, and obtaining inclination measuring data measured by the inclination measuring probe;
and S5, extracting effective measuring point data sections from the inclination measuring data, intercepting the stable data sections, calculating the average value, and calculating the inclination angle information of the corresponding measuring point position.
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CN202110762412.9A CN113638735B (en) | 2021-07-06 | 2021-07-06 | Manual-automatic integrated non-electric connection drilling inclinometer and measuring method |
PCT/CN2021/107495 WO2023279438A1 (en) | 2021-07-06 | 2021-07-21 | Manual and automatic integrated non-electric connection borehole inclinometer and measurement method |
US17/401,339 US11840918B2 (en) | 2021-07-06 | 2021-08-13 | Manual/automatic non-electric-connection borehole clinometer and measurement method |
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